Optimization of Investment Casting Process for Stainless Steel Impeller with Complicated Geometry

doi:10.11901/1005.3093.2015.12.955

Chinese Journal of Materials Research

2015, Vol. 29

Issue (12): 955-960 DOI: 10.11901/1005.3093.2015.12.955

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Optimization of Investment Casting Process for Stainless Steel Impeller with Complicated Geometry

Jian ZHAO^1,^*(

),Chunlei YI²

1. School of Material Science and Engineering, Shandong University of Science and Technology, Qingdao 266590, China
2. Science and Technology Parks, Shandong University of Science and Technology, Qingdao 266590, China

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Jian ZHAO,Chunlei YI. Optimization of Investment Casting Process for Stainless Steel Impeller with Complicated Geometry. Chinese Journal of Materials Research, 2015, 29(12): 955-960.

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Abstract

Due to the complicated geometry and thin wall of the stainless steel impeller, during the investment casting process, some casting defects such as shrinkage porosity and filling shortage are usually produced, which have a close relationship with the filling and solidification process. So, the software ProCast was used to study the filling and solidification process of impeller and the numerical simulation results were compared with the experimental results in this paper. The following results can be acquired: 1. when the pouring temperature is 1550℃ and the casting speed is 0.75 m/s, the investment casting impeller can be filled to avoid the filling shortage defect; 2. although the appropriate pouring temperature and casting speed can avoid the filling shortage defect, but it can not avoid the shrinkage porosity defects in the impeller casting; 3. to pre-place certain cold iron in the middle of the impeller casting mold according to its structural characteristics can eliminate the shrinkage porosity defects. When the height of the pre-placed cold iron is 1/3 of the height of the inner cavity of impeller mold, the effectiveness in elimination the defects in the castings is the best thereby a high quality impeller can be acquired.

Key words: synthesizing and processing techniques investment casting stainless steel impeller filling and solidification casting defects

Received: 26 September 2014

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https://www.cjmr.org/EN/10.11901/1005.3093.2015.12.955 OR https://www.cjmr.org/EN/Y2015/V29/I12/955

Table 1 Thermal parameters and process parameters of 304 stainless steel

Table 2 Thermal parameters of 304 stainless steel

Fig.1 Geometry and finite element model of investment casting impeller

Fig.2 Filling casting with different velocity (a) 0.5 m/s, (b) 1.25 m/s, (c) 0.75 m/s

Fig.3 Filling casting with different casting temperature (a) 1500℃, (b) 1550℃

Fig.4 Impeller casting solidification and shrinkage porosity defect map

Fig.5 Different placement of cold iron

Fig.6 Impeller casting solidification and shrinkage porosity defect map with cold iron

Fig.7 Impeller casting after improved Investment casting process

1	YANG Bingbing, The processes research on large complicated stainless steel impeller by melting modules-sand mould composite casting, PhD Dissertation, Xi'an University of Technology (2007)
1	(杨兵兵, 大型复杂不锈钢叶轮熔模-砂型复合铸造工艺的研究, 博士学位论文, 西安理工大学(2007))
2	JIANG Buju, Investment casting, (Beijing, Machinery Industry Press, 2004)p.309
2	(姜不居, 熔模精密铸造, (北京, 机械工业出版社, 2004)p.309)
3	LI Feng, ZHENG Fusheng, WANG Gang, DAI Penglong, ZHANG Jie, Numerical simulation of solidification Process for Impeller Investment Casting Based on ProCAST, Hot Working Technology, 42(7), 55(2013)
3	(李峰, 郑福生, 王刚, 戴朋龙, 张洁, 基于ProCAST的叶轮熔模铸造凝固过程数值模拟, 热加工工艺, 42(7), 55(2013))
4	SHI Yuanjin, ZHANG Zhanchang, LIU Rui, Shrinkage defects improvement of steel casting investment casting based on flow field optimization, Foundry, 163(9), 910(2014)
4	(石远进, 张战场, 刘睿, 基于流场优化的熔模铸钢件缩孔缺陷改善, 铸造, 163(9), 910(2014))
5	YAN Kai, LIU Hanwu, DU Yunhui, ZHANG Hui, Dynamic Simulation of the Filling Process and Temperature FieldAnalysis of Al-4%Cu Alloy in Solidification, Foundry Technology, 30(2), 510(2009)
5	(严恺, 刘汉武, 杜云慧, 张慧, Al-4%Cu合金凝固充型过程动态模拟及温度场分析, 铸造技术, 30(2), 510(2009))
6	YAO Binye, MAO Hongkui, XU Hong, MENG Xianbao, Status and development trend of numerical simulation of flow field in casting process, Foundry Technology, 33(10), 1211(2012)
6	(姚宾叶, 毛红奎, 徐宏, 孟宪宝, 铸造充型过程流场数值模拟现状及发展趋势, 铸造技术, 33(10), 1211(2012))
7	XIONG Shoumei, XU Qingyan, KANGJinwu, Casting process simulation technology, (Beijing, Machinery Industry Press, 2004)p.39
7	(熊守美, 许庆颜, 康进武, 铸造过程模拟仿真技术, (北京, 机械工业出版社, 2004)p.39)
8	DENG Kang, SUN Huanchun, Treatment of latent heat in calculations for solidification of heavy castings, Journal of Dalian University of Technology, 32(5), 531(1992)
8	(邓康, 孙焕纯, 大型铸件凝固计算中的潜热处理方法, 大连理工大学学报, 32(5), 531(1992))
9	LI Donghui, GAO Yunbao, XIN Qibin, QiuYiqing, LIU Xianghua, WANG Guodong, The processing method and application study for latent heat releases in alloy castings, Foundry, 53(12), 1005(2004)
9	(李东辉, 高云宝, 辛启斌, 邱以清, 刘相华, 王国栋, 铸件凝固潜热的处理方法与应用研究, 铸造, 53(12), 1005(2004))

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